FI82674B - OVER ANCHORING FOR BOMBERING AV GLASSKIVOR. - Google Patents

Description

1 82674

The present invention relates to a method for conveying thermoplastic material, in particular glass sheets, using an upper mold against which the sheets are pressed, and optionally a lower mold, in particular an annular lower mold, to which the loose sheets are placed, and in which method, before the plates 10 are pressed against the upper mold, a gas flow rising from below is applied to them so that the flow supports part of the weight of the plates.

The upper mold is of a type similar to that described in French Patent Nos. 2,085,464 and 8604962, i.e. it is connected to a suction sink and the suction of the sink acts at the extreme edge of the mold, thus causing the plates, in particular glass, to adhere to said mold. The upper mold can also be of another type described in EP patent 20 3 391, namely it can consist of a single element pierced by holes through which a vacuum acts.

Convex plates, of which, for example, only glass plates are taken, although the plates can be made of any thermoplastic material, raise the upper mold either due to suction acting in the extreme region (FR patents 2,085,464 and 8604962) or through the upper mold (EP patent 3,391) or due to the upward flow of gas against the glass sheet so as to elevate the glass sheet (EP Patent 5,306).

30

The placement of the glass sheets under the upper mold must be very precise, especially when said upper mold is curved.

When the glass sheets arrive on top of the conveyor, it is quite possible to check the stopping position of the glass sheets under the upper mold in the longitudinal direction of the conveyor thanks to locks, for example of the type described in FR patent 8513801.

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In contrast, orientation and placement transverse to the direction of travel are more difficult to control. It is, of course, possible, as is now the case, to determine the position of the glass sheets already on the upstream side before they go to the heating furnace 5 which precedes the conveying point. After a few experiments, it is possible to determine the position to be given to the glass plates on the upstream side of the oven so that they stop in the right place under the top-tilting mold. But this causes fading, requires numerous repairs, 10 does not provide extreme accuracy and does not protect the discs from accidental damage during transport.

It is also possible to place the glass plate re-centering devices under the upper mold, but this causes said plates to rub against their substrate, especially the conveyor rollers, which may damage the glass surface and if the efforts to re-center the plate edges are really .

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It is an object of the present invention to enable the centers, in particular glass, to be centered by eliminating and at least minimizing the surface and edge abrasions and defects caused by the centering of the panels. The method according to the invention is characterized in that during the operation of the gas flow, the plates are moved by centering devices in order to bring them into the desired position.

It is preferred that this gas stream be hot so as not to cause the convex plates to cool.

It is preferred that the dynamic blowing pressure corresponds to 5-30 mm of the water column when conveying glass sheets with thicknesses typically used in a car or building, i.e. about 3 or 4 millimeters.

The invention also relates to an apparatus for carrying out the method, comprising a convex apparatus with an upper convex mold against which glass sheets introduced on a substrate, such as a conveyor, can be pressed, and a pressurized gas chamber 12 with an upper barrier wall 13 with a plurality of openings 14 below and under the base of the glass-5 plates, and which is intended to blow an upward vertical flow of gas to support a portion of the weight of the glass plates. The apparatus is characterized in that it also comprises glass plate centering devices with which the glass plates can be moved during the rising gas flow 10.

It is preferred, when the plates are supported by a conveyor, that before the upper mold adheres to the plates, these centering devices move in the longitudinal direction of the plates so as to re-center said plates as they arrive.

The invention will now be described in more detail following the accompanying drawings, in which:

Fig. 1 is a general diagram of an apparatus for conveying glass sheets, Fig. 2 is a diagram of partial feed devices placed under a convex mold, and Fig. 3 is a diagram of reconcentration devices.

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Figure 1 shows an assembly of a conveying apparatus utilizing an upper mold and a lower mold as well as a hardening site extending to the conveying site.

Of course, the invention remains the same if the hardening point is replaced by a stress relief or application point or the like.

Figure 1 schematically shows a glass heating furnace: 35 1, a conveying place 2 and a tempering place 3. The roller conveyor 4 passes through the furnace 1 and brings the glass sheets 5 under an upper conveying mold 6 placed inside a space 7 whose temperature is kept high. The mold 6 shown is of the type described in the aforementioned 4,867,464 FR patent 2,085,464, i.e. it is connected to a suction sink 8 and the vacuum acts in the extreme region of the mold 6. This mold 6 moves upwards. The lowering mold 9, either a frame or a ring or even a frame 5 mounted on the carriage 10, can be designed to receive each glass sheet 5 after it has been relaxed by the upper mold 6. This carriage 10 moves on the rails 11 so that it can be moved under the mold 6 and then moved outside the conveying place 2, for example to bring the glass sheets 5 to the tempering place 3, which is a continuation. The glass sheets loosened by the upper mold 6 complete their convexity by bending over the lower mold 9.

According to the invention, there is at least a pressurized gas space 12 located below the convexity point 2, the upper surface of which has a barrier wall 13 with a plurality of openings 14, simple holes.

In the embodiment shown in Figure 2, this space 12 of compressed gas is supplied by the fan 15, for example by transverse flow.

This fan 15 and this space 12 belong to a blower assembly comprising heating electrical devices 17 of the supply channel 16, 25 of the fan 15, placed at the tip of the supply channel 16 to heat the gas stream to the required temperature for glass at about 650 ° C, recovering the blown hot gas placed above the top dip mold 6 for, a recirculation line 19, movable valves 20 for varying the flow rate of the blown gas, and vertical baffles 21 for smoothing the flow of gas.

By adjusting the operation of the fan 15 and / or changing the position of the vent-35 bricks 20, the flow rate of hot gas, especially air, can be controlled so that a homogeneous dynamic pressure of 5 to 30 mm from the water column and preferably 5 to 15 mm from the water column exists under the glass sheets.

5 82674 This pressure is adjusted according to the thickness and thus according to the weight of the treated glass sheets.

Thus, this gas flow can support a portion of the weight of the glass sheets, from ten percent to some tens of percent (up to 80%) of the total weight.

It follows that the transport of glass sheets on the conveyor rollers is always safe, but since the weight of the glass sheets 10 is felt less, all re-centering of said sheets by sliding on their substrate can be done with less abrasion than without bottom blowing and thus causing less or no blowing. no deterioration of the glass surface at all and less effort on the edges 15 of the glass. The blow pressure limit is reached when the glass would no longer remain on its base, especially on the conveyor, in which case transport would no longer be possible without a suitable additional traction device. Just before this limit state, the support on the conveyor would no longer be sufficient to ensure a sufficiently precise stopping of the glass in its longitudinal direction of travel.

Transverse centering devices for glass sheets are of the type hooks, guide rails, belts, etc., which are placed along the path of the glass sheets as these hooks or guide rails move transversely to support the glass edges, push them and also to accommodate different sizes of glass.

It is preferred that these centering devices move longitudinally at the same time as the glass sheets.

These may be belts 30 as shown in Figure 3, each of which rotates around two cylinders 31, 32, and each unit 35 is mounted on a washer 33 which is movable in the direction of the glass by means of a lever 34.

6 82674 The direction of push of these re-centering devices is transverse to the longitudinal direction of travel of the glass. Of course, if necessary, longitudinal centering devices could also be introduced.

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It is not only the case that, thanks to these centering devices, which operate by nullifying part of the weight of the glass by means of a rising blow, the quality of the glass does not deteriorate but the re-centering operation is much no-10 faster than in the absence of blowing.

This re-centering can, of course, be done on individual glass sheets as well as on stacks of glass sheets. This re-centering, without causing a change in the laser, is of particular importance, especially in the case where glass sheets are given complex shapes, in which case the placement of the glass under the upper convex mold requires extreme precision.

Claims (7)

7 82674 A method for conveying sheets of thermoplastic material, in particular glass, which method uses an upper mold against which the sheets are pressed, followed by possibly 5 lower molds, in particular annular lower molds, to which the loose sheets are placed and subjected to pressing the sheets against the upper mold. a gas flow rising from below so that the flow supports part of the weight of the plates, characterized in that during the operation of the gas flow the plates are moved by centering devices to bring them into the desired position. Method according to Claim 1, characterized in that, when the plates are glass, the gas flow is heated to a temperature of the order of 650 ° C. A method according to claim 1 or 2, characterized in that the dynamic blowing pressure is about 5-30 mm H 2 O, preferably about 5-15 mm H 2 O with a glass thickness of about 3 or 4 mm. Method according to one of the preceding claims, characterized in that the ascending gas flow carries 10 to 80% of the total weight of the glass sheets. Apparatus for carrying out the method according to any one of the preceding claims, comprising a convex apparatus with an upper convex mold against which the glass sheets introduced on a substrate, such as a conveyor, can be pressed, and a pressurized gas chamber (12) with upper barrier walls (13) with a plurality of openings (14) and arranged below the upper mold and under the base of the glass sheets, and intended to blow an upwardly vertical gas flow to support a part of the weight of the glass sheets, characterized in that it also comprises glass sheet centering devices with which the glass sheets can be moved during the rising gas flow. 8 82674 Device according to Claim 5, characterized in that the centering devices are arranged on the side of the inlet path of the glass sheets below the upper convex mold. 5 Device according to Claim 5 or 6, characterized in that the gas flow blown under the glass sheets is provided by a wind tunnel comprising essentially a fan (15), heating devices (17), a suction hood (18), a circulating line, valves and baffles.